Integrated field, model, and theoretical advances inform a predictive understanding of transport and transformation in the critical zone

Authors

Joel Singley, Roger Williams UniversityFollow
Martin Briggs, United States Geological Survey
Beth Hoagland, S.S. Papadopulos & Associates
Rachel Lauer, University of Calgary
Jessie Meeks, Colorado School of Mines
Aaron B. Regberg, NASA Johnson Space Center
David M. Rey, United States Geological Survey
Kenny Swift Bird, Colorado School of Mines
Adam S. Ward, Oregon State University

Document Type

Article

Publication Title

Journal of Hydrology

Publication Date

6-1-2023

Abstract

Dr. Kamini Singha's work has been transformative in advancing our predictive understanding of transport and transformation in Earth's critical zone. She integrates empirical, numerical, and theoretical advances at scales spanning individual pores to regional aquifers, and works seamlessly across disciplines to connect otherwise disparate fields. Her work has both applied and basic research dimensions, ensuring advances inform best practices across the industry. That she has achieved prominence in research while maintaining a successful portfolio of teaching, mentoring, and service to the profession is particularly impressive. Indeed, Singha has fostered the burgeoning discipline of hydrogeophysics and ensured that this discipline, and its role in critical zone science, is an open, accessible, and welcoming field. Here, we summarize Singha's impact on hydrologic science as a researcher, educator, mentor, and agent of change in the field.

Volume

621

DOI

10.1016/j.jhydrol.2023.129653

Recommended Citation

Singley, J., Briggs, M., Hoagland, B., Lauer, R., Meeks, J., Regberg, A., Rey, D., Bird, K., & Ward, A. (2023). Integrated field, model, and theoretical advances inform a predictive understanding of transport and transformation in the critical zone. Journal of Hydrology, 621 https://doi.org/10.1016/j.jhydrol.2023.129653

ISSN

00221694